Evolutionary Processes Shaping Postglacial Gene Pools of High-Altitude Forests: Evidence from the Endemic Eucalypts of Tasmania

Climatic changes during the Pleistocene were responsible for dramatic redistributions of plant species worldwide. On the rugged southern hemisphere island of Tasmania, temperature increases following the last glaciation saw upslope migration of climatically suitable species from lowland refugia and...

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Bibliographic Details
Published in:Forests 2023-06, Vol.14 (6), p.1072
Main Authors: Jones, Rebecca C., Harrison, Peter A., Hudson, Corey J., Hirst, Cate A., Matthews, Alexander T., Rouger, Romuald, Wise, Sascha L., O’Reilly-Wapstra, Julianne M., Wiltshire, Robert J. E., Jordan, Gregory J., Vaillancourt, René E., Potts, Brad M.
Format: Article
Language:English
Subjects:
Adaptation
Alpine environments
Altitude
Altitudes
Biological evolution
Chloroplast DNA
Chloroplasts
Climate change
Deoxyribonucleic acid
DNA
Environmental aspects
Environmental gradient
Eucalyptus
Forests
Genetic aspects
Glaciation
Glaciology
Greenhouses
Haplotypes
High altitude
Highlands
Hybridization
Morphology
Natural history
Natural selection
Phylogenetics
Plant species
Pleistocene
Populations
Quantitative genetics
Refugia
Seedlings
Southern Hemisphere
Subalpine environments
Survival
Taxa
Trees
Woodlands
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Summary:Climatic changes during the Pleistocene were responsible for dramatic redistributions of plant species worldwide. On the rugged southern hemisphere island of Tasmania, temperature increases following the last glaciation saw upslope migration of climatically suitable species from lowland refugia and the expansion of eucalypt-dominated forests and woodlands in the Central Highlands. We integrate multiple lines of evidence (chloroplast and nuclear DNA markers, seedling morphology, and survival in common garden experiments) from a group of closely related endemic eucalypts (the alpine white gums) to argue that (i) the Central Highlands of the island were colonised by multiple glacial refugia with hybridisation among species and previously separated populations, and (ii) natural selection has filtered the admixed populations, resulting in local adaptation to the harsh sub-alpine environment. Chloroplast haplotype diversity decreased and nuclear microsatellite diversity increased with altitude, chloroplast sharing among taxa was common, and nuclear DNA differentiation of morphologically distinct taxa was lower in the Central Highlands compared with lowland regions. Local adaptation in the highlands was signalled by evidence from (i) a glasshouse trial in which directional selection (QST > FST) had shaped seedling morphological trait variation and (ii) population survival differences in 35-year-old reciprocal plantings along the major environmental gradients. We conclude that the evolutionary response of these island endemic trees to past climate change has involved the interplay of both hybridisation and natural selection, highlighting the importance of maintaining species interactions under future climate change.
ISSN:1999-4907
1999-4907
DOI:10.3390/f14061072